CN114171282B

CN114171282B - Electromagnetic unlocking mechanism

Info

Publication number: CN114171282B
Application number: CN202111293829.1A
Authority: CN
Inventors: 于洁云; 易红宝
Original assignee: Shenzhen Zanty Electronics Co ltd
Current assignee: Shenzhen Zanty Electronics Co ltd
Priority date: 2021-11-03
Filing date: 2021-11-03
Publication date: 2022-06-10
Anticipated expiration: 2041-11-03
Also published as: CN114171282A

Abstract

The embodiment of the invention discloses an electromagnetic unlocking mechanism, which comprises a bushing, a shell, a magnetic suction piece and a locking piece, wherein the shell and the magnetic suction piece are sleeved on the bushing, a sealed accommodating space is formed between the inner wall of the shell and the outer wall of the bushing, and a permanent magnet and an electromagnet are arranged in the accommodating space; the magnetic attraction piece and the shell are arranged in a relatively moving mode. The locking piece moves along with the magnetic attraction piece and is used for locking or unlocking an object. In the electromagnetic unlocking mechanism, when the electromagnet is not electrified, the magnetic attraction piece is attracted to the shell by the permanent magnet, and the locking piece locks an object; the magnetic field that the electromagnet produced after circular telegram is opposite with the magnetic field direction of permanent magnet to make magnetism inhale piece and shell separation, locking piece unblock object. The on-off action of the locking piece can be realized by controlling the on-off of the electromagnet, and the automatic control of the underwater switch is realized.

Description

Electromagnetic unlocking mechanism

Technical Field

The invention relates to the technical field of underwater operation, in particular to an electromagnetic unlocking mechanism.

Background

With the development of science and technology, more electrical products are applied to underwater operation engineering to help complete underwater exploration, underwater photography, buoy operation and the like. In some specific scenes, a movable switch is required to be additionally arranged on an underwater cable to control the equipment to be started, the existing underwater switch cannot realize automatic control, and manual operation is mainly performed by divers, so that the underwater working efficiency is lowered, and the operation safety cannot be guaranteed.

Disclosure of Invention

In view of this, the invention provides an electromagnetic unlocking mechanism, which is used for solving the problem that an underwater switch in the prior art cannot be automatically controlled.

The invention provides an electromagnetic unlocking mechanism, which is characterized by comprising:

the bushing is sleeved on the cable;

the shell is sleeved on the bushing, a sealed accommodating space is formed between the inner wall of the shell and the outer wall of the bushing, and a permanent magnet and an electromagnet are arranged in the accommodating space;

the magnetic suction piece is sleeved on the bushing and is arranged in a relative movement mode with the shell;

the locking piece moves along with the magnetic attraction piece and is used for locking or unlocking an object;

when the electromagnet is not electrified, the magnetic attraction piece is attracted to the shell by the permanent magnet, and the locking piece locks an object; the magnetic field generated after the electromagnet is electrified is opposite to the magnetic field of the permanent magnet in direction, so that the magnetic attraction piece is separated from the shell, and the locking piece unlocks the object.

Optionally, an elastic element is arranged between the magnetic attraction element and the housing, when the electromagnet is not powered on, the magnetic attraction element is attracted to the housing by the permanent magnet, and the elastic element is in a compressed state;

after the electromagnet is electrified, the magnetic field at the position where the magnetic part is located is weakened, and the elastic part rebounds to drive the magnetic part to be separated from the shell.

Optionally, a positioning ring is arranged on the bushing, and an end portion of the shell connected with the magnetic attraction piece is sleeved on the positioning ring;

and a sealing ring is arranged between the positioning ring and the shell.

Optionally, the electromagnet is connected with a power supply line, the bushing is provided with a through hole for the power supply line to pass through, and a power taking end of the power supply line is communicated with a power supply from the inside of the bushing;

and a sheath is arranged in the through hole and used for filling a gap between the power supply line and the inner wall of the through hole.

Optionally, a sealant is arranged in the accommodating space to fill the gap.

Optionally, the casing, the magnetic attraction member, and the positioning ring are made of a magnetic conductive material, the bushing includes a magnetic conductive first bushing and a non-magnetic conductive second bushing, and the positioning ring is located on the first bushing;

the shell, the piece is inhaled to magnetism, the holding ring and first bush forms the magnetic conduction return circuit of permanent magnet.

Optionally, one end of the first bushing, which is far away from the housing, is provided with a first connecting portion, the inner wall of the second bushing is provided with a second connecting portion, and the first connecting portion and the second connecting portion can be in sealing fit so that the two electromagnetic unlocking mechanisms are connected end to end.

Optionally, the outer wall of the bushing is provided with a limiting portion spaced from the housing, and the magnetic attraction member moves in a spaced area between the limiting portion and the housing.

Optionally, the permanent magnet fixing device comprises a fixing seat for installing the permanent magnet, the fixing seat is sleeved on the bushing in a circular ring shape, and a plurality of installation positions for placing the permanent magnet are uniformly and symmetrically arranged on the fixing seat.

Optionally, a through hole is formed in the magnetic part, and the through hole communicates a connection gap between the magnetic part and the housing with the outside to balance the pressure difference.

The embodiment of the invention has the following beneficial effects:

in the electromagnetic unlocking mechanism, when the electromagnet is not electrified, the magnetic attraction piece is attracted to the shell by the permanent magnet, and the locking piece locks an object; the magnetic field that the electromagnet produced after circular telegram is opposite with the magnetic field direction of permanent magnet to make magnetism inhale piece and shell separation, locking piece unblock object. The on-off action of the locking piece can be realized by controlling the on-off of the electromagnet, and the automatic control of the underwater switch is realized.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Wherein:

fig. 1 is a schematic structural diagram of an electromagnetic unlocking mechanism in one embodiment.

Fig. 2 is a schematic view of the fitting structure of the bushing and the housing in the embodiment shown in fig. 1.

FIG. 3 is a top view of an embodiment of a mounting base.

Fig. 4 is a schematic structural diagram of two electromagnetic unlocking mechanisms connected in series.

In the figure:

110. a first bushing; 112. a limiting part; 114. a first connection portion; 120. a second bushing; 122. a through hole; 124. a sheath; 130. a permanent magnet; 140. an electromagnet; 142. a framework; 144. a coil; 146. a power supply line; 150. a positioning ring; 160. a seal ring; 170. a fixed seat; 172. an installation position; 200. a housing; 210. An accommodating space; 220. a second connecting portion; 300. a magnetic member; 310. a locking member; 400. an elastic member.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The invention provides an electromagnetic unlocking mechanism which is sleeved on a cable and is lowered to an underwater operation area along with the cable, and is used for completing equipment unlocking action in underwater operation engineering.

Referring to fig. 1 and 2, an exemplary electromagnetic unlocking mechanism is shown in cross-section in an embodiment:

the electromagnetic unlocking mechanism comprises a bushing, a magnetic attraction piece 300 sleeved on the bushing and a shell 200, a sealed accommodating space 210 is formed between the outer coin of the bushing and the inner wall of the shell 200, and a permanent magnet 130 and an electromagnet 140 are arranged in the accommodating space 210. The permanent magnet 130 and the electromagnet 140 respectively generate magnetic fields with opposite directions, the magnetic field generated by the permanent magnet 130 enables the magnetic attraction piece 300 to be adsorbed on the shell 200, the electromagnet 140 generates a magnetic field with the opposite direction to the permanent magnet 130 after being electrified, and the two magnetic fields mutually offset to enable the magnetic attraction piece 300 to lose the adsorption force and be separated from the shell 200. The magnetic element 300 is provided with a locking element 310 for opening and closing (i.e. locking and unlocking an object), and the locking element 310 moves along with the magnetic element 300 to complete the opening and closing operation.

The locking member 310 may be any structure capable of performing the above-mentioned switching action, including but not limited to a hook, a latch, etc.

Specifically, the bushing is in direct contact with the cable as a cushioning and insulating member, with the remaining members all fitting over the outer wall of the bushing.

Further, an elastic member 400 is disposed between the magnetic attraction member 300 and the housing 200. When the magnetic attraction piece 300 is attracted to the housing 200, the elastic piece 400 is in a compressed state, and the attraction force of the permanent magnet 130 to the magnetic attraction piece 300 is greater than the resilience force of the elastic piece 400. When the electromagnet 140 is charged, a magnetic field opposite to the permanent magnet 130 is generated, and the two magnetic fields cancel each other out, so that the attraction force generated by the permanent magnet 130 to the magnetic attraction piece 300 is smaller than the resilience force of the elastic piece 400, and the magnetic attraction piece 300 is separated from the housing 200.

Optionally, a limiting portion 112 is provided on the bushing. The magnetic member 300 is disposed at a space between the position-limiting portion 112 and the housing 200, and the magnetic member 300 moves within the space. The magnetic attraction piece 300 can only be separated from the shell 200 but not from the lining, thereby facilitating the recovery of the parts after operation.

In order to make the stress of the magnetic attraction piece 300 more stable, in the electromagnetic unlocking mechanism provided by the present invention, the magnetic attraction piece 300 and the housing 200 are made of magnetic conductive materials, and the bushing includes a magnetic conductive first bushing 110 and a non-magnetic conductive second bushing 120, so that the housing 200, the magnetic attraction piece 300 and the first bushing 110 form a magnetic conductive loop, and the magnetic induction line is confined in the components forming the magnetic conductive loop, so that the magnetic attraction piece 300 is more stable in stress.

On the other hand, the second bushing 120 is not magnetic conductive, the magnetic induction lines inside the limiting structure only form a loop on one side of the magnetic member 300, and one side of the second bushing 120 is not magnetic conductive, so as to avoid magnetic leakage. The running safety of the mechanism is improved.

In one embodiment, a magnetically permeable retaining ring 150 is provided on the liner. The retaining ring 150 acts to limit the position of the housing 200 on the liner. As shown in fig. 1, the end of the housing 200 for connecting the magnetic member 300 is disposed on the positioning ring 150.

Further, a sealing ring 160 is disposed between the positioning ring 150 and the housing 200. The sealing ring 160 can fill the gap between the positioning ring 150 and the housing 200 to ensure airtightness in the accommodating space 210.

It is worth mentioning that the sealing ring 160 is made of a non-magnetic material. The sealing ring 160 without magnetic conductivity forms a layer of isolation between the casing 200 and the bushing, so that the magnetic induction line cannot directly form a loop through the contact between the casing 200 and the bushing, but sequentially passes through the casing 200, the magnetic attraction member 300 and the positioning ring 150 and then contacts with the bushing to form a loop.

The electromagnet 140 illustratively includes a power supply wire 146, a coil 144 that can be energized, and a bobbin 142 for winding wire. The frame 142 is sleeved on the bushing. The power supply line 146 is communicated with the coil 144, and the other end is a power taking end and is connected with a power supply.

The power take-off end of the power supply line 146 is routed through the bushing from the gap between the inner wall of the bushing and the outer skin of the cable.

Further, in order to ensure airtightness in the accommodating space 210, a sheath 124 is provided in the through hole 122. The sheath 124 is sleeved outside the power supply line 146, and can play a role in fixing the power supply line 146 and fill a gap between the power supply line 146 and the through hole 122 to prevent water seepage.

Referring to fig. 3, fig. 3 is a top view of the fixing base 170 according to an embodiment. In the present embodiment, the permanent magnet 130 is mounted on the fixing base 170. The fixing base 170 is annular and is sleeved outside the bushing. The fixing base 170 is provided with a plurality of uniform and symmetrical mounting positions 172 along the outer circumferential surface of the bushing.

Different numbers of permanent magnets 130 are placed on the fixing base 170, so that the magnitude of the magnetic force generated by the permanent magnets 130 on the magnetic attraction member 300 can be artificially controlled according to the requirement. It should be noted that, in order to ensure the annular force of the magnetic attraction member 300 is balanced, the mounting positions 172 on the fixing base 170 should be centrosymmetric, and the permanent magnets 130 should also be distributed on the fixing base 170 centrosymmetrically.

Sealant is poured into the accommodating space 210 to form a sealant injection layer, gaps are filled, and parts such as the permanent magnet 130, the electromagnet 140 and the like are sealed in the sealant, so that the sealing performance is further improved, and internal corrosion caused by electric leakage and water seepage is avoided.

The electromagnetic unlocking mechanism provided by the invention can be used in series in some scenes. Correspondingly, the electromagnetic unlocking mechanism is provided with a first connecting portion 114 and a second connecting portion 220 at two ends thereof, respectively. Optionally, referring to fig. 1 and 2 and fig. 4, fig. 4 is a schematic diagram of two electromagnetic unlocking mechanisms connected in series. The housing 200 covers one end of the bushing, the other end of the bushing is exposed, and the first connection part 114 is an exposed end of the bushing; the second connection portion 220 is disposed on an inner wall of the second bushing 120. The first connecting portion 114 of one electromagnetic unlocking mechanism can be matched and connected with the second connecting portion 220 of the other electromagnetic unlocking mechanism, so that the two electromagnetic unlocking mechanisms are connected end to end.

The first connection portion 114 and the second connection portion 220 are in sealing engagement.

Optionally, a through hole is formed in the magnetic suction piece, and the through hole communicates a connection gap between the magnetic suction piece and the shell with the outside to balance the pressure difference.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention, and it is therefore to be understood that the invention is not limited by the scope of the appended claims.

Claims

1. An electromagnetic unlocking mechanism, comprising:

the bushing is sleeved on the cable;

the locking piece is positioned on the magnetic suction piece, moves along with the magnetic suction piece and is used for locking or unlocking an object;

when the electromagnet is not electrified, the magnetic attraction piece is attracted to the shell by the permanent magnet, and the locking piece locks an object; the direction of a magnetic field generated after the electromagnet is electrified is opposite to that of a magnetic field of the permanent magnet, so that the magnetic attraction piece is separated from the shell, and the locking piece unlocks an object;

an elastic part is arranged between the magnetic part and the shell, when the electromagnet is not electrified, the magnetic part is adsorbed on the shell by the permanent magnet, and the elastic part is in a compressed state;

2. The electromagnetic unlocking mechanism of claim 1, wherein the bushing is provided with a positioning ring, and the end of the housing connected with the magnetic attraction piece is sleeved on the positioning ring;

and a sealing ring is arranged between the positioning ring and the shell.

3. The electromagnetic unlocking mechanism according to claim 2, wherein the electromagnet is connected with a power supply line, the bushing is provided with a through hole for the power supply line to pass through, and a power taking end of the power supply line is communicated with a power supply from the inside of the bushing;

4. The electromagnetic unlocking mechanism of claim 2, wherein a sealant is provided in the accommodating space for filling the gap.

5. The electromagnetic unlocking mechanism of claim 2 wherein said housing, said magnetically attractive member and said positioning ring are all magnetically conductive materials, said bushings including a magnetically conductive first bushing and a magnetically non-conductive second bushing, said positioning ring being located on said first bushing;

the shell, the magnetic attraction piece, the positioning ring and the first bushing form a magnetic conduction loop of the permanent magnet.

6. The electromagnetic unlocking mechanism according to claim 5, wherein a first connecting portion is provided at an end of the first bushing away from the housing, a second connecting portion is provided at an inner wall of the second bushing, and the first connecting portion and the second connecting portion can be in sealing fit so that the two electromagnetic unlocking mechanisms are connected end to end.

7. The electromagnetic lock release mechanism according to claim 1, wherein a stopper portion spaced from the housing is provided on an outer wall of the bushing, and the magnetic member moves in a spaced area between the stopper portion and the housing.

8. The electromagnetic unlocking mechanism of claim 1, comprising a fixed seat for mounting the permanent magnet, wherein the fixed seat is annularly sleeved on the bushing, and a plurality of mounting positions for placing the permanent magnet are uniformly and symmetrically arranged on the fixed seat.

9. The electromagnetic unlocking mechanism of claim 1, wherein the magnetic member has a through hole, and the through hole connects the connection gap between the magnetic member and the housing to the outside to balance the pressure difference.